DE3201417A1 - TRANSPORT ROLLER AND ROLLER RANGE FOR TRANSPORTING HOT MATERIAL - Google Patents

Description

The invention relates to a transport roller and a transport roller section for the transport of 'hot material, in particular hot metal pieces, while preventing heat from being radiated therefrom. In particular The invention relates to a transport roller and a transport roller line for transporting hot slabs or Blocks emerging from a mold or heating oven.

Conventional transport rollers for the transport of steel blocks or slabs, which were previously used in steel production and used in rolling mills consist of heat-resistant, fixed or hollow cylindrical rollers. For transport rollers that have very hot pieces, such as hot slabs from the Continuous casting or hot slabs or ingots resulting from a heating or slab manufacturing step transport a subsequent procedural stage, occur different Difficulties arise. The rolls of the rolling line tend due to the direct transfer from the hot material and the absorbed radiant heat to thermal fatigue. The rollers also draw heat from the warm material, causing a considerable drop in temperature. Eventually the roll surfaces suffer a considerable deformation.

Recently it has been in terms of energy saving and high productivity, a lot of work was spent on developing a direct rolling method that would produce the one from the continuous casting mold emerging hot casting or the slab or block coming from the slab production directly to the subsequent one Rolling stage is performed.

Such a hot casting, slab or ingot (hereinafter referred to as "hot material") becomes continuous

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transported with the help of a transport device from the previous to the next processing stage. To carry out of direct rolling, it is of particular importance that the temperature drop of the hot material on its way is kept as low as possible by the transport device.

Because the hot material is in direct contact with the transport rollers that are used in the transport device, its heat is transferred to the cold transport rollers and radiated in all directions. As a result, there is such a sharp drop in the temperature of the material that that it is very difficult to transport it to the rolling stand before its temperature falls below that in the rolling stage required minimum temperature falls. So far, no transport roller has been proposed which is used for such a direct rolling process is satisfactory.

As part of the work that led to the present invention, an attempt was first made to the Urafangsflache the To make transport rollers that come into direct contact with the hot material as small as possible. These were Grooves are provided on the circumferential surface of the roller. However, the result of this measure was not so remarkable as was expected. The reason for this is believed to be in cold See air currents occurring in the grooves around the transport rollers as the rollers rotate. This draft cools the hot material.

Another unexpected difficulty also arose. Namely, it was found that at the bottom of the grooves the tendency to form cracks arises. These cracks occur because of the repeated thermal stress on the ground the grooves. Attempts have therefore been made to apply a heat-resistant tape to the bottom of the grooves in order to reduce the heat shock. This did have a certain effect in terms of

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Prevention of the occurrence of cracks achieved. However, the air currents that cool the hot material could do so not be turned off.

The invention has for its object to provide a transport roller which has very little heat from the hot Material pulls off and is still so strong that its circumferential surface is hardly damaged. Another The object of the invention is to provide a transport roller track with which the temperature drop of the hot material is reduced considerably and the occurrence of uneven temperature distribution in the longitudinal direction and can be prevented in both cross-sectional directions of the hot material. After all, it's a job the invention to provide a transport roller line for transporting a hot casting from a continuous casting mold, with which the transported hot casting is then subjected to a direct rolling process on an industrial scale can be subjected.

These objects are achieved by the invention. The invention relates to that characterized in the claims Object.

The invention is explained in more detail with reference to the drawing. It means:

Fig. 1 is a schematic front view of a transport roller

according to one embodiment of the invention; 30th

2-6 are partial cross-sections of transport rollers of the invention;

Figures 7 and 8 are cross sections of transport rollers of the invention;

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9 is a schematic view of a transport roller line of the invention;

10 shows a cross section through the structure of a transport device;

Fig.11 is a horizontal section showing the type of fastening shows movement of the transport roller;

Figure 12 is a horizontal section showing an embodiment of a top heat insulating hood or cover and shows a heat insulating panel;

Fig. 13 is a plan view showing the manner of attachment of the shows upper heat insulating hood;

Fig. 14 is a plan view showing the method of fastening the heat-insulating Panel shows;

Fig.15 is a partial cross-section showing an embodiment shows a mounting pin;

16 shows a schematic longitudinal section through the transport device;
25th

Fig. 17 (a) is a schematic side view of the upper heat insulating Hood;

Fig. 17 (b) is a schematic horizontal cross section through the upper heat-insulating cover;

Fig. 18 is a view showing the location of a laser beam position indicator shows; and

Fig. 19 is a schematic view showing the type of control shows the entire device of the invention.

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The transport roller of the invention has annular concave grooves (hereinafter referred to as "grooves") on its peripheral surface on. The grooves are covered with a heat-insulating material almost up to the level of the roller surface fills. The heat insulating fabric is made up of one or more Layers of a wrap held in place to prevent it from falling due to centrifugal force during rotation the transport roller or as a result of the deterioration in its quality due to the action of the heat of the hot material falls out of the grooves.

The transport roller of the invention is intended to draw as little heat as possible from the hot material carried on it will. In order to increase the service life of the transport roller used to transport hot material, the Use of a hollow roller can be thought of, which is cooled with a coolant. However, a hollow roller pulls considerably Heat and would therefore not meet the most important requirements of the invention. As a result, must

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according to the invention a solid roller can be used to the To keep the heat loss of the hot material as small as possible and also to ensure that the roller is high Has strength.

The invention will now be explained in more detail with reference to the drawing.

Fig. 1 is a schematic front view of the transport roller of the invention. The surface 10a of the roller 10 has a plurality of circumferential grooves 2a to 2h. The grooves 2 can be formed by various methods for example when casting the roll, by cutting or machining the cast roll or by fastening of sleeve-like convex parts on the roll surface. The remainder of the roll surface is 3a to 3i thus the part that comes into contact with the hot material. The grooves 2a to 2h are with the heat insulating Stuffed fabric.

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The width and number of the roller surfaces 3a to 3i and the grooves 2a to 2h depend on the weight and the temperature the hot material being transported and the degree of heat loss prevention desired Results are obtained with an embodiment of the invention in which the length of the cylindrical roller body 1500 to 1800 mm, the roller diameter 400 to 450 mm and both the surface width of the roller and the width of the grooves are 80 to 250 mm. However, the invention is not limited to this embodiment.

The heat insulating fabric for the grooves and the winding layer wound thereover are described below.

Figures 2 to 6 are partial cross-sections through the transport roller of the invention. The heat-insulating material for the grooves 2a can be rock wool, slag wool, glass wool, ceramic wool or a similar known heat-resistant material, such as Be fireclay. These substances can be used individually or in combination. A suitable amount of binder or hardener can be added or mixed in.

The thickness of the heat-insulating material should be determined in view of its heat-retaining effect. she may vary depending on the properties of the substance or substances chosen. Usually one thickness is sufficient Range from 5 to 30 mm. Of course, a thicker layer of insulating material is more effective. The strength of the However, the roll can be deteriorated because the grooves must then be deeper.

(a m band a us J The winding layer 7 may, for example ausfeinem Meta11-wire or consist of sheet metal that is wound in such intervals through the heat insulating material 6, that the material from falling from the roll surface is prevented. The heat-insulating material is thus partially to the

Exposed roller surface. Level 8, i.e. the difference in altitude between the roll surface and the surface of the heat insulating cloth is preferably as small as possible. If it is too small, however, there is a risk that either the heat insulating fabric or the winding layer will be hot

Touching material and scratching or pitting it. Good results will be with a step with a height in the range of Get 3 to 20 mm.

Fig. 3 shows an embodiment _t in the winding layer

band-shaped

th 7a to 7c made of a / metal mesh with the heat insulating Fabric are connected in a layer structure 6a to 6c. Even if this construction is a bit more expensive to manufacture, it is very durable and has a long operating time.

Fig. 4 shows another embodiment in which the groove is filled with a heat insulating substance 6d to which a self-hardening substance such as a ceramic fiber is added. The heat insulating material thereby obtained is wrapped with winding layers 7d and 7e, each of which consists of a single wire. The advantage of this embodiment is that it can be manufactured in a very short time. In this embodiment are also metal sleeves 41 and 42 attached around the roller body 10 by shrinkage, which give the grooves between the sleeves 41 and 42.

Fig. 5 is another embodiment in which a molded heat insulating fabric 6e made of ceramic fiber is arranged in the groove and wrapped with a winding layer 7f, which consists of a net-like, thread-like, heat-resistant material such as a ceramic fabric or cord. This embodiment can also be easily manufactured and is highly effective, but also relatively expensive.

Fig. 6 shows another embodiment in which a number of metal pins 9 at the bottom of the groove 2a

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Welding or a similar type is attached. The groove is filled with slag wool 6f. After that, a spray is used 7h, consisting of a device from a self-curing, heat-resistant spray, such as a heat-resistant powder, and an inorganic binder (which may also contain an organic substance) sprayed thereon to provide a heat insulating Layer to get.

Fig. 7 shows another embodiment in which the heat insulating Fabric 6g was previously formed in the form of two half-rings.

Fig. 8 shows a further embodiment of the invention at of a plurality of sheet-like heat insulating fabrics 6h in a multilayer form around the outside of the roller body 10 is wound.

Since the grooves arranged around the roller surface do not contribute anything to the support of the hot material, the load becomes accordingly increased on the metal layer of the roller. This affects the life of the roller. From the point of view In order to increase the durability of the metal surface it is therefore desirable to strengthen it in order to increase its resistance to heat and wear. For example, a sleeve can be made stainless steel with excellent heat and wear resistance. It can a similar material can also be attached to the metal surface of the roller by constructive welding. The metal surface can also be hardened by spraying a metal.

The thickness of the reinforced layer is preferably in the range of about 5 to 30 mm from the roll surface. if the difference in thermal conductivity and thermal expansion between the roller and the reinforced layer is large, there is preferably an intermediate layer between

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arranged them.

It has been found that the transport roller of the invention reduces heat loss by 40 to 80% and an increase in service life by 1.1 to 1.5 times in comparison to conventional transport rollers is achieved. Because the surface of the roller that is in contact with the hot material In addition, the damage caused by heat is also very small.

Research has also been carried out on transport roller routes performed to reduce heat loss and damage to the roll surface. It was a new transport roller line developed.

The transport roller line of the invention consists of transport rollers, which are arranged in series in the direction of transport of the hot material. Here is the surrounding surface 10a of each transport roller provided with grooves that contain a heat insulating material, which surfaces 4a to 4h. The rollers also have contact metal surfaces 3a to 3i which are in contact with the hot material 1 coming. The use of the transport roller section of the invention increases the service life of the transport rollers and achieves a large reduction in the amount of heat drawn from the hot material.

Figure 9 is a top plan view of the transport roller line of the invention. Transport rollers 10b to 10e are in the direction of the Transports arranged, which is indicated by the arrow 75 in FIG. The hot material (slab) 1 is through the dashed line indicated.

In FIG. 9, the transport roller 10b and the adjacent transport roller 10c are offset from one another in the forward direction, so that the contact metal surface 3a of the roller 10b

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^ with the heat-insulated surface 4f of the roller 10c in the transport direction is in the same line. This staggered arrangement is also used with the other transport rollers. So is located The surface 4f of the roller 10c is in the same line with 3g of the roller 10d and this in turn with 4g of the roller 1Oe. In other words, the contact metal surfaces of a transport roller are in line with the heat-insulating surfaces of the next transport roller in the transport direction of the hot material 1. In this case however, it is preferable that the width of the heat insulating surface 4f is larger than that of the contact metal surface 3a.

Correspondingly, it follows from the above-explained arrangement of the contact metal surfaces and the heat-insulating surfaces the transport roller that the heat loss due to heat conduction is greatly reduced, since the bottom of the hot material 1 only for every second transport roller

comes into contact with the metal surface. 20th

The difference in effectiveness between the transport roller line of the invention and that of the prior art is as follows: The durability of the roller line of the invention is 10 to 50% longer. Therefore, their service life is also extended. The roller train of the invention brings about a reduction in heat loss of 5 to 40% compared to conventional trains. In one embodiment of the invention, the temperature drop over 50 m when the direct ^{rolling process is used is 150 °} C. lower in the roller section of the invention than in a conventional roller section.

Another embodiment of the transport roller line of the invention is described below. Fig. 10 is a Cross-section through a transport device, which is a transport roller track contains. This consists in this version

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Approximate shape from rotatable with the help of bearings 13 on racks 12 attached transport rollers 10; see the cross section in 11. A plurality of transport rollers 10 are arranged along the transport direction of the hot material 1. In Fig. 11 denotes 15 an electric motor, which the transport

roller 10 drives. The transport roller 10 is provided with a number of grooves 2 around its circumferential surface. The grooves 2 are filled with a heat insulating material such as ceramic fiber.
10

As shown in Fig. 9, the contact metal surface is 3a in the arrangement of the transport roller section 10 offset from the heat-insulating surface 4f.

Gaps between the transport rollers 10, for example the gaps between the rollers 10b and 10c, contain heat-insulating Panels 17. An upper heat-insulating hood 16 is removably arranged over the transport roller path.

Fig. 12 is a cross section through a Ausftihrungsforra Rolling line of the invention and shows the heat-insulating panels 17 and the upper heat-insulating hood 16. In this Embodiment has the upper heat-insulating hood 16 a frame 61, the inside of which is covered with a heat insulating material 62 to provide heat insulation to improve. The upper heat insulating hood 16 is attached to a support frame 63 which has a Holding member 18 is firmly connected to the base 12.

In addition, a fastening pin 21 is shown in FIG. 12, that, as will be explained below, the upper thermally insulating hood 16 at a greater than specified movement hinders either in the transverse or in the transport direction. 22 denotes a sealing washer. The upper thermal insulation

Rende hood 16 can be easily attached or removed by removing the fastening pin 21. In a similar way

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Way, the heat insulating board 17 is made of a plate-shaped Frame 71, which is lined with a heat-insulating material 72. The panel 17 is removable on one Holding member 18a attached, which has a fastening pin 21a is connected to the base 12a.

FIG. 13 is a plan view showing an example of attachment of the heat insulating panel 17. One of the mounting holes 73, through which the fastening pin 21a is guided, is somewhat larger in diameter than the fastening pin 21a and is designed concentrically therewith. The remaining Holes are shaped as slot-like holes 7 3a that are larger in width and length than the mounting pins 21a. Since the heat insulating board 17 is attached close to the hot material 1, it expands when heated and contracts again. With the arrangement described, the heat insulating panel 17 can freely move inside a specified area expand and contract, since the mounting holes 7 3 with a long slot with the fixing pins 21a are connected. Damage to the panels 17 as a result of thermal stress can thus be effectively prevented.

The thermal stress prevention device described above has been used in conjunction with the heat insulating Table 17 described. However, a similar device can also be used for the upper heat-insulating hood 16 are provided. For example, as shown in Fig. 14, the upper heat insulating hood 16 in a corresponding Number of units to be divided. Each unit will then have a similar arrangement of the mounting holes provided as explained above. For example, a circular hole 65 and an elongated hole 65a provided with fastening pins 21 for the same purpose. with regard to the fastening pins 21 and 21a it should be noted that that they should not be screwed tightly underneath

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Using a known nut or split pin. As indicated in FIGS. 12 and 15, they work better when they depend on their own weight through holes 73, 73a and 65, 65a. If necessary, the lower part can of the fastening pins 21 or 21a in a removal preventing manner, for example a widening b, the arises from elastic deformation, be formed.

In the arrangement described above, the mounting pins are 21 and 21a are not screwed, but are held by their own weight and can therefore be easily removed. It was also found experimentally that the pressure at the contact surface between the support frame 63 and the holding member 18 or between the heat insulating panel and the holding member 18a is almost equal to the weight the upper heat-insulating hood 16 or the heat-insulating Table 17 is. Effective absorption of thermal expansion and contraction as shown in FIGS. 13 and 14 can therefore be fully realized. 20th

As explained above, in the transport device of the invention, the area of the transport path between the Rollers 10 closed by the heat-insulating panels 17, while the space above the transport roller route through the upper heat insulating hood 16 is covered. This is the transport path through which the hot material 1 is guided is built almost like a closed tunnel. In addition, the transport rollers 10 with contact metal surfaces 3a and heat insulating surfaces 4a equipped in a staggered arrangement, so that not only a temperature drop of the hot Materials 1 can be prevented as a whole, but also local temperature drops.

In a further embodiment of the invention is a Number of openings for indicator beams at the height of the transport of the hot material in the transport device

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provided in which the space above the transport rollers is covered with a heat-insulating hood. This allows the hot material in the almost completely closed Facility to be transported. A number of laser beam position indicators, equal to the number of openings, is arranged in positions corresponding to the height of the openings. A control unit is also provided which gives the motor the command to drive the transport rollers, when a signal is received from the laser beam position indicator. The transport device with the laser beam position indicator is particularly effective for the operation of the transport roller line of the invention.

Fig. 16 is a schematic longitudinal section through the inventive Transport device to prevent heat loss, in which the hot material 1 on transport rollers 10a to 10e is transported in an almost closed state. The upper heat insulating hoods 16a, 16b and 16c, respectively are designed as a semi-closed space, are removable on lateral supports 18a to 18c in the direction of transport attached to precisely cover the group of transport rollers. In Fig. 16 is a plurality of heat insulating Panels 17a to 17e are provided between the transport rollers 10a to 10e. They are removable on the straps for that Transport rollers attached (not shown in the figure).

A plurality of saddle-type heat insulating auxiliary hoods or covers 26a and 26b are provided to allow greater play when attaching the heat-insulating hoods 16a to 16c. With this arrangement, the columns, which compensate for the thermal expansion of the heat insulating hoods 16a to 16c are provided to be closed.

The transport device having the above-mentioned structure can have a high effect in terms of prevention of heat loss can be achieved because an im

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essentially closed structure is present. The hot material (slab) is completely shielded from external observation. The control of the transport process could therefore be imprecise.
5

In another embodiment of the invention, which is shown in 17 (a) and (b), each side of the heat insulating hood 16b is provided with openings 27a and 27b, through which an indicator light beam passes. According to FIG. 18, a laser beam position indicator 29, which consists of a laser beam Transmitter 29a and a receiver 29b is attached to the openings 27a and 27b opposite one another. This arrangement enables the hot material to be transported safely and accurately without any substantial rise of heat loss, since the operation of the transport rollers can be controlled on the basis of the signals received, if the hot slab interrupts the laser beam.

The openings 27a and 27b can be closed by a heat-resistant glass or another translucent material.

lam frame 1 66 den. In Fig. 18 a heat insulating layer 62a ^ is attached.

brought and a protruding metal member 28 is provided, in order to prevent direct contact of the hot slab 1 with the heat insulating layer 62a. 25th

19 shows a schematic overview of an embodiment the control device of the invention. The device has a laser beam position indicator 29, which consists of a pair of devices 29a, 29b and a further pair 29c and 29d. Electric motors 15a to 15g are provided for driving the transport rollers 10a to 10g. They are electrically connected to a drive unit 31, which contains an electrical circuit. A control device 32 issues a drive command to the drive device 31 in response to an input signal from the laser beam position indicator 29. For example, receives

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the control device 32 receives the input signals via circles 33 and 34 from the laser beam position indicators for the drive of the transport rollers in the preceding and following stages (not shown). Then the control device 32 gives Via the circles 35 and 36 the commands for the control of the drive device for the transport rollers of the preceding and following stages in order to smoothly transport a plurality Ensure hot pieces at a set distance between them.

A laser beam position indicator is used because the hot material being transported is generally a luminous one Body is at high temperature and the light radiation from the hot slab is inside the heat-insulating hood is reflected. Therefore, an ordinary photoelectric detector would often malfunction.

The invention has been explained in connection with the direct rolling of a hot casting that is produced from a continuous casting process comes. However, the transport roller of the invention can also be used in other technical fields.

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Claims (18)

VOSSIUS · VOSSIUS T ^ Ü-CiHNfeR -MEUNEMANN · RAUH PATENTANWÄLTE * SI E BERTSTRASSE Λ · 8OOO MÜNCHEN 86 · PHONE: (O 8β) 474Ο75 CABLE: BEN 2 O UP ATENT MÖNCHEN · TELEX 9-28 453VOPAiOB 320U17 ( Ra / H) January 19, 1982 Case: 640 NIPPON STEEL CORPORATION Tokyo, Japan - "Transport roller and transport roller line for transporting hot material" claims 1. Transport roller for transporting hot material, characterized in that it (10) is a solid metal roller / which on its surface / (2a) - (2hÜ before with a number of ring-shaped circumferential grooves "provided which are filled with a heat insulating material. 2. Roller according to claim 1, characterized in that the heat insulating material is a body with a suitable shape. 3. Roller according to claim 1, characterized in that the heat-insulating material is a molded body made of two half-rings is. 4. Roller according to claim 1, characterized in that the heat insulating material is a self-curing heat-resistant Fabric is. L J 5. Roll according to claim 1, characterized / that the heat insulating material is shaped as a tape '. 6. Roller according to claim 1, characterized in that the heat insulating material by a plurality of pins attached to the roller attached to the bottom of the grooves. 7. Roller according to claim 1, characterized in that the outer layer of the contact metal surface of the roller represents a heat and wear-resistant layer. 8. Transport roller for transporting hot material, thereby characterized in that it is a solid metal roller with a number of annular, umlauf -'- fenden, provided with grooves filled with a heat-insulating material and one or more winding layers that hold the heat-insulating fabric in place. 9. Roller according to claim 8, characterized in that the winding layers consist of a metal wire or metal mesh tape exist, 10. Roller according to claim 8, characterized in that the winding layers are made of an incombustible, heat-resistant, heat-insulating fiber mesh or fabric. 11. Roll according to claim 8, characterized in that the winding layers are made of a self-curing, heat-resistant Consist of substance. 12. Roll according to claim 8, characterized in that the Winding layers are formed as a plurality of layers, the non-woven layers of heat insulating Material included in between. L -J 13. Roll according to claim 8, characterized in that the heat insulating material from a body with matching Form and the winding layer is a layer of a self-curing spray material. 14. Roll according to claim 8 / characterized in that the heat insulating fabric is held by a plurality of pins attached to the bottom of the grooves, that the winding layers consist of a net-like tape and are held by the pins and that a layer of heat-resistant, heat-insulating spray material on the winding layer of the reticulated. Band is formed. 15. Transport roller for transporting hot material, thereby characterized by being a fixed metal roller from represents, which on their surface with a number / ring-shaped, circumferential, concave, up to close to the level of the surface of the metal roller with a heat-insulating material filled grooves and provided with winding layers on the heat-insulating fabric. 16. Transport roller track for transporting hot material, characterized in that it has a number of Has transport rollers which are arranged in the transport direction of the hot material, consist of solid metal rollers and on their surfaces a number / ring-shaped, circumferential concave Have grooves, the contact metal surfaces of each transport roller in line with the heat insulating Surfaces of the adjacent transport rollers are arranged. 17. roller line according to claim 16, characterized in that the concave, with the heat insulating Fabric-filled grooves are wider than the contact metal surfaces of the rollers. L -J ^ 18. roller line according to claim 16, characterized in that that a number of transport rollers are rotatably mounted on pedestals / freely removable heat-insulating panels, which closes the space between adjacent transport rollers 5 feet, and an upper heat-insulating hood is provided which covers the transport roller route and is removably attached to the base. L ■ J